CN112019075B - High-gain single-phase inverter, control method and three-phase inverter - Google Patents

Abstract

The invention provides a high-gain single-phase inverter which comprises a direct-current power supply, a first inductor, a second inductor, a first capacitor, a second bidirectional switch, a first bidirectional switch, a fifth switching tube and a fifth diode. When the gain to be achieved is less than 0 or the gain to be achieved is greater than 1, the high-gain single-phase inverter works in a first working mode, namely a discontinuous inverter working mode at the moment, and when the gain to be achieved is less than 0 and less than 1, the discontinuous inverter working mode cannot meet working conditions at the moment, the high-gain single-phase inverter is switched to a second working mode, and the high-gain single-phase inverter continues to work through a voltage reduction circuit, so that the high gain is realized. The invention also provides a control method of the high-gain single-phase inverter and a three-phase inverter.

Description

High-gain single-phase inverter, control method and three-phase inverter

Technical Field

The invention relates to the technical field of inverters, in particular to a high-gain single-phase inverter, a control method and a three-phase inverter.

Background

The inverters are divided into voltage source inverters and current source inverters, and most of the conventional voltage source inverters are voltage reduction circuits, that is, the output ac voltage is lower than the input dc voltage. Therefore, at present, many applications are that a first stage Boost circuit (such as a Boost circuit) is added before an inverter circuit, so that the inverter becomes a two-stage structure, the size is increased, and the system stability is reduced, so that it is important to research a single-stage high-gain inverter, and therefore, researchers propose a Z-source inverter, which is an impedance network formed by two inductors and two capacitors, and can realize a Boost function, so that extensive research is performed.

The current leakage problem of a non-isolated inverter system is mainly solved by two ideas, one idea is that through topology and modulation, scholars at home and abroad propose a plurality of improved topological structures which can be mainly divided into a single-inductor structure and a symmetrical inductor structure, wherein the symmetrical inductor structure can be divided into a direct current side bypass structure and an alternating current side bypass structure, and typical structures comprise H5, H6, improved H6, mixed H6, HERIC and other topological structures. Although these improved topologies and controls reduce leakage current to some extent, they are also only suppressive and do not address the leakage current problem at its root. The other idea is to use a topology structure with input and output being in common with ground, the generation of the leakage current is due to the parasitic capacitance between the photovoltaic array and the ground, and meanwhile, because of the isolation effect of no transformer, the current passes through the parasitic capacitance to form a loop in the circuit, so that the leakage current is generated, and if the topology with input and output being in common with ground is constructed, the parasitic capacitance can be bypassed, so that the problem of the leakage current is fundamentally solved.

In the prior art, for example, "Low-Cost Semi-Z-source Inverter for Single-Phase photo-voltaic Systems" refers to two inverters shown in fig. 1 and fig. 2, one Inverter is named as a Semi-Z source Inverter (as shown in fig. 1), and the other Inverter is named as a Semi-quasi-Z source Inverter (as shown in fig. 2), compared with a traditional Z source Inverter, only two switching tubes are used, meanwhile, an impedance network of a Z source is reserved, but a through state of the Z source is not utilized, more, common ground of input and output is realized, and the leakage current problem is thoroughly solved, but the circuit has a great disadvantage that the forward gain of the two proposed topologies can only reach 1 at most, and the negative gain can reach infinity, so that the Inverter can only reach 1-time gain at most.

In the prior art, for example, chinese patent (application) cn201810654075.x (a high-gain single-phase single-stage transformer-free photovoltaic inverter and a control method thereof) and CN201910693423.9 (a high-gain three-switch inverter and a control method thereof):

in terms of cost: both of the above two patents (applications) apply a large number of passive components (7 inductors and capacitors), and the number of switching devices and independent diodes is 3 in cn201810654075.x and 5 in CN201910693423.9, which results in high cost;

in terms of efficiency: in the topology and control of the two patents (applications), too many elements are passed through on a current circulation path, element loss is increased, and a plurality of groups of series-parallel loops of inductors and capacitors exist, so that internal reactive current is large, the current stress of a device is increased, and the efficiency is further reduced.

Disclosure of Invention

The invention aims to provide a high-gain single-phase inverter, a control method and a three-phase inverter, and aims to solve the problem that the existing inverter can only achieve 1-time gain at most.

The invention provides a high-gain single-phase inverter, which comprises a direct-current power supply, a first inductor, a second inductor, a first capacitor, a second bidirectional switch, a first bidirectional switch, a fifth switching tube and a fifth diode, wherein the first inductor is connected with the first diode; the positive electrode of the direct-current power supply is respectively connected with the first end of the first inductor and the first end of the fifth switching tube; the second end of the first inductor is respectively connected with the first end of the first bidirectional switch and the first end of the first capacitor; a second end of the fifth switching tube is connected with an anode of the fifth diode, and a cathode of the fifth diode is respectively connected with a second end of the first capacitor, a first end of the second bidirectional switch and a first end of the second inductor; the second end of the second inductor is connected with the second end of the first bidirectional switch and the first end of the second capacitor respectively; and the negative electrode of the direct current power supply, the second end of the second bidirectional switch and the second end of the second capacitor are connected together.

The high-gain single-phase inverter firstly obtains the Msin omega t (modulation wave of the gain to be achieved) of the high-gain single-phase inverter, when the gain to be achieved is less than 0 or more than 1, the high-gain single-phase inverter works in a first working mode, namely a discontinuous inverter working mode at the moment, when the gain to be achieved is less than 0, the discontinuous inverter working mode cannot meet working conditions, the high-gain single-phase inverter is switched to a second working mode, and a voltage reduction circuit continues to work, so that high gain is achieved; in addition, because the switching devices work alternately, the overall efficiency is obviously improved.

Further, the second bidirectional switch comprises a first switch tube and a fourth switch tube, and the first bidirectional switch comprises a second switch tube and a third switch tube.

The invention also provides a control method of the high-gain single-phase inverter, which is used for the high-gain single-phase inverter and comprises the following steps: when the gain to be achieved is less than 0 or >1, the high-gain single-phase inverter is in a first working mode, in the first working mode, the fifth switching tube is kept turned off, at the moment, the first switching tube, the second switching tube, the third switching tube and the fourth switching tube work in a matched mode to invert, wherein the second switching tube and the third switching tube are driven to be the same, the first switching tube and the fourth switching tube are driven to be the same, and the first working mode comprises two working states; the first working state: the first switching tube and the fourth switching tube are conducted, and the second switching tube and the third switching tube are disconnected; the second working state: the first switching tube and the fourth switching tube are turned off, and the second switching tube and the third switching tube are turned on; when the gain of 0< the gain to be achieved <1, the working mode of the intermittent inverter cannot meet the working condition at the moment, the intermittent inverter is switched to a second working mode, when the second working mode is adopted, the second switching tube and the third switching tube are kept turned off, the fourth switching tube is kept turned on, a voltage reduction type conversion circuit is formed by the fifth switching tube, the fifth diode, the first switching tube and the second inductor, the first switching tube and the fifth switching tube work in a matched mode to reduce the voltage, and the second working mode comprises two working states; the third working state: the fifth switching tube is switched on, and the first switching tube is switched off; the fourth working state: the fifth switching tube is turned off, and the first switching tube is turned on.

The invention also provides a three-phase inverter, which comprises three high-gain single-phase inverters, wherein the three high-gain single-phase inverters are connected in parallel, and the alternating current output end of each high-gain single-phase inverter is used as the three-phase alternating current output end of the three-phase inverter.

Drawings

FIG. 1 is a prior art topology block diagram designated as a Semi-Z source inverter;

FIG. 2 is a prior art topology diagram of a designated Semi-quad-Z source inverter;

fig. 3-1 is a topology structure diagram of a high-gain single-phase inverter provided by the present invention;

3-2-3-9 are schematic diagrams of different structures of a first bidirectional switch in the high-gain single-phase inverter in FIG. 3-1;

FIG. 4 is a topological block diagram of a first mode of operation of the high gain single phase inverter of FIG. 3-1;

FIG. 5 is a topology diagram of a first operating state of the high gain single phase inverter of FIG. 4;

FIG. 6 is a topology diagram of a second operating state of the high gain single phase inverter of FIG. 4;

FIG. 7 is a topological block diagram of a second mode of operation of the high gain single phase inverter of FIG. 3-1;

FIG. 8 is a topology diagram of a third operating state of the high gain single phase inverter of FIG. 7;

FIG. 9 is a topology diagram of a fourth operating state of the high gain single phase inverter of FIG. 7;

fig. 10 is a strategy diagram of a control method of a high-gain single-phase inverter according to a second embodiment of the present invention;

fig. 11 is a topology structural view of a three-phase inverter in a third embodiment of the invention;

description of main circuit symbols:

first inductor	L1	Fifth switch tube	S5	First bidirectional switch	SS1
						Second inductor	L2	First capacitor	C	Second bidirectional switch	SS2
First switch tube	S1	Second capacitor	Co	Input voltage	Vin
						Second switch tube	S2	Direct current power supply	DC	Fifth diode	D
Third switch tube	S3	Load voltage	Vo	Third diode	D3
						Fourth switch tube	S4	Load(s)	R	Fourth diode	D4
First diode	D1	Second diode	D2

The following detailed description will further illustrate the invention in conjunction with the above-described figures.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Several embodiments of the invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 3-1, a high-gain single-phase inverter according to a first embodiment of the present invention includes a DC power source DC, a first inductor L1, a second inductor L2, a first capacitor C, a second capacitor Co, a second bidirectional switch, a first bidirectional switch, a fifth switch tube S5, and a fifth diode D; the positive electrode of the direct current power supply DC is respectively connected with the first end of the first inductor L1 and the first end of the fifth switching tube S5; a second end of the first inductor L1 is connected to a first end of the first bidirectional switch and a first end of the first capacitor C, respectively; a second end of the fifth switching tube S5 is connected to an anode of the fifth diode D, and a cathode of the fifth diode D is connected to the second end of the first capacitor C, the first end of the second bidirectional switch, and the first end of the second inductor L2, respectively; a second end of the second inductor L2 is connected to a second end of the first bidirectional switch and a first end of the second capacitor Co, respectively; the negative electrode of the direct current power supply DC, the second end of the second bidirectional switch, and the second end of the second capacitor Co are connected together, and it can be understood that, where grounding is required, the negative electrode of the direct current power supply DC is grounded.

It is understood that first bidirectional switch SS1 may have the structure shown in fig. 3-2 through 3-9 in addition to the structure shown in fig. 3-1.

In the structure of the first bidirectional switch SS1 shown in fig. 3-1 to 3-8, the first bidirectional switch SS1 includes a second switch tube S2, a third switch tube S3, a second diode D2, and a third diode D3; the second switch tube S2 is connected in series with the third diode D3 in the same direction (i.e., the first end of the second switch tube S2 is connected to the cathode of the third diode D3, or the second end of the second switch tube S2 is connected to the anode of the third diode D3) to form a second branch; the third switching tube S3 and the second diode D2 are connected in series in the same direction (i.e., the first end of the third switching tube S3 is connected to the cathode of the second diode D2, or the second end of the third switching tube S3 is connected to the anode of the second diode D2) to form a first branch; the current outflow end of the first branch is connected with the current inflow end of the second branch to form a first end of a first bidirectional switch SS1, and the current inflow end of the first branch is connected with the current outflow end of the second branch to form a second end of a first bidirectional switch SS 1; the first branch midpoint M1 is a connection point of the third switching tube S3 and the second diode D2, and the second branch midpoint M2 is a connection point of the second switching tube S2 and the third diode D3 (M1 and M2 are not labeled in fig. 3-1). In the first bidirectional switch SS1 configuration shown in fig. 3-6, first branch midpoint M1 and second branch midpoint M2 are not connected, while in the first bidirectional switch SS1 configuration shown in fig. 3-1, 3-2, 3-7, and 3-8, first branch midpoint M1 and second branch midpoint M2 are connected; in practice, connecting the first branch midpoint M1 with the second branch midpoint M2 in fig. 3-3 is the structure of the first bidirectional switch SS1 in fig. 3-1; connecting the first branch midpoint M1 with the second branch midpoint M2 in fig. 3-4 is the structure of the first bidirectional switch SS1 in fig. 3-2; connecting the first branch midpoint M1 with the second branch midpoint M2 in fig. 3-5 is the structure of the first bidirectional switch SS1 in fig. 3-7; connecting the first branch midpoint M1 with the second branch midpoint M2 in fig. 3-6 is the structure of the first bidirectional switch SS1 in fig. 3-8.

It is understood that the structure of the first bidirectional switch SS1 shown in fig. 3-1 to 3-8 can also be applied to the second bidirectional switch SS2, and the corresponding names and serial numbers can be adjusted as follows: the first bidirectional switch SS1 is adjusted to be a second bidirectional switch SS2, the second switch tube S2 is adjusted to be a first switch tube S1, the third switch tube S3 is adjusted to be a fourth switch tube S4, the second diode D2 is adjusted to be a first diode D1, the third diode D3 is adjusted to be a fourth diode D4, the first branch is adjusted to be a third branch, the second branch is adjusted to be a fourth branch, the first branch midpoint M1 is adjusted to be a third branch midpoint M3, and the second branch midpoint M2 is adjusted to be a fourth branch midpoint M4. After adjustment, the method is as follows: the second bidirectional switch SS2 comprises a first switch tube S1, a fourth switch tube S4, a first diode D1 and a fourth diode D4; the first switch tube S1 is connected in series with the fourth diode D4 in the same direction (i.e. the first end of the first switch tube S1 is connected to the cathode of the fourth diode D4, or the second end of the first switch tube S1 is connected to the anode of the fourth diode D4) to form a fourth branch, the fourth switch tube S4 is connected in series with the first diode D1 in the same direction (i.e. the first end of the fourth switch tube S4 is connected to the cathode of the first diode D1, or the second end of the fourth switch tube S4 is connected to the anode of the first diode D1) to form a third branch, the current flowing end of the third branch forms the first end of the second bidirectional switch SS2, and the current flowing end of the third branch forms the second end of the second bidirectional switch SS 2; a fourth branch midpoint M4 (i.e., a connection point between the first switch tube S1 and the fourth diode D4) (M3 and M4 are not shown in fig. 3-1), and a third branch midpoint M3 (i.e., a connection point between the fourth switch tube S4 and the first diode D1); the third branch midpoint M3 and the fourth branch midpoint M4 may be unconnected or may be connected together.

In the embodiment of the present invention as shown in fig. 3-1, the first switching tube S1, the second switching tube S2, the third switching tube S3, and the fourth switching tube S4 are IGBTs, and the first end and the second end thereof are respectively a collector and an emitter of the IGBT; it is understood that in other embodiments of the present invention, the first switch tube S1, the second switch tube S2, the third switch tube S3 and the fourth switch tube S4 may be any one of a triode, an IGBT, a MOSFET or other types of switch tubes, for example, the first switch tube S1 is a MOSFET, the second switch tube S2 is an IGBT, the third switch tube S3 is a MOSFET, and the fourth switch tube S4 is an IGBT; for another example, the first switch tube S1 is an IGBT, the second switch tube S2 is a MOSFET, the third switch tube S3 is an IGBT, the fourth switch tube S4 is a MOSFET, and so on. When the nth (N = one, two, three, four) switching tube Sn (N =1, 2, 3, 4) is a triode, the first end and the second end of the nth (N = one, two, three, four) switching tube Sn (N =1, 2, 3, 4) are respectively a collector and an emitter of the triode; when the nth (N = one, two, three, four) switching tube Sn (N =1, 2, 3, 4) is a MOSFET, the first end and the second end of the nth (N = one, two, three, four) switching tube Sn (N =1, 2, 3, 4) are respectively a drain electrode and a source electrode of the MOSFET; when the nth (N = one, two, three, four) switching tube Sn (N =1, 2, 3, 4) is an IGBT, the first end and the second end of the nth (N = one, two, three, four) switching tube Sn (N =1, 2, 3, 4) are a collector and an emitter of the IGBT, respectively; wherein, N is one, N =1, and when N is two, N = 2; n =3 when N is three; n is four, N = 4.

In the structure of the first bidirectional switch SS1 shown in fig. 3-9, the first bidirectional switch is composed of one IGBT and four diodes, wherein the cathodes of two diodes are connected to the first end (i.e., the collector) of the IGBT, the anodes of the two diodes are connected to the cathodes of the other two diodes, respectively, and the anodes of the other two diodes are connected to the second end (i.e., the emitter) of the IGBT.

It is understood that the IGBT in the configuration of first bidirectional switch SS1 shown in fig. 3-9 may be replaced by other types of switching tubes, such as MOSFET or triode, etc. When the switch tube is an MOSFET, the first end and the second end of the switch tube are respectively a drain electrode and a source electrode of the MOSFET; when the switch tube is a triode, the first end and the second end of the switch tube are respectively a collector and an emitter of the triode.

It is to be understood that the structure of the first bidirectional switch SS1 shown in fig. 3-9 can also be used as the structure of the second bidirectional switch SS 2; of course, the first bidirectional switch SS1 and the second bidirectional switch SS2 may have other structures as long as the bidirectional current flow can be controlled.

In fig. 3-1, the fifth switching tube S5 is a combination of an IGBT and a diode connected in anti-parallel with the IGBT, and in this case, the first and second ends of the fifth switching tube are the collector and emitter of the IGBT, respectively, and it is understood that the fifth switching tube S5 may also be a combination of a triode and a diode connected in anti-parallel with the triode (in this case, the first and second ends of the fifth switching tube S5 are the collector and emitter of the triode, respectively), a combination of a MOSFET and a diode connected in anti-parallel with the MOSFET (in this case, the first and second ends of the fifth switching tube S5 are the drain and source of the MOSFET, respectively), or a MOSFET (in this case, the first and second ends of the fifth switching tube S5 are the drain and source of the MOSFET, respectively).

When the gain to be achieved is less than 0 or the gain to be achieved is greater than 1, the high-gain single-phase inverter works in a first working mode, namely a discontinuous inverter working mode at the moment, and when the gain to be achieved is less than 0 and less than 1, the discontinuous inverter working mode cannot meet working conditions at the moment, the high-gain single-phase inverter is switched to a second working mode, and the high-gain single-phase inverter continues to work through a voltage reduction circuit, so that the high gain is realized.

As shown in fig. 4, in this embodiment, in the high-gain single-phase inverter, the first operating mode is provided, in which the fifth switching tube S5 is kept off, and at this time, the first switching tube S1, the second switching tube S2, the third switching tube S3 and the fourth switching tube S4 cooperate to perform inversion, wherein the second switching tube S2 and the third switching tube S3 are driven the same, and the first switching tube S1 and the fourth switching tube S4 are driven the same, and the first operating mode includes two operating states, i.e., a first operating state and a second operating state.

As shown in fig. 5, the first operating state: the first switch tube S1 and the fourth switch tube S4 are turned on, and the second switch tube S2 and the third switch tube S3 are turned off, at this time, Vin = VC + VL1 and VL2= VCo, which can be obtained by kirchhoff' S voltage law.

As shown in fig. 6, the second operating state: the first switch tube S1 and the fourth switch tube S4 are turned off, and the second switch tube S2 and the third switch tube S3 are turned on, which can be derived from kirchhoff' S voltage law, Vin = VL1+ VCo, and VC = VL 2.

Assuming that the duty cycles of the first switch tube S1 and the fourth switch tube S4 are Du, the duty cycles of the second switch tube S2 and the third switch tube S3 are 1-Du, and combining the above expressions, the following expressions can be obtained according to the volt-second equilibrium law,

Du*(Vin−VC)+(1−Du)*(Vin−VCo)=0，

VCo*Du+(1−Du)*VC=0；

VL1 is the voltage across the first inductor L1, VL2 is the voltage across the second inductor L2, VCo is the output voltage, and VC is the voltage across C, as follows.

VCo/Vin = (1-Du)/(1-2 Du) can be obtained. From the relational expression between the output voltage VCo and the input voltage Vin (i.e., the dc power voltage), it can be seen that when Du is changed from 0 to 0.5, the positive gain is changed from 1 to positive infinity, and when Du is changed from 0.5 to 1, the negative gain is changed from negative infinity to 0, so that the mode operates in the discontinuous inverter operating mode, and the positive gain portion of 0-1 is absent.

As shown in fig. 7, in this embodiment, in the second operating mode, the second switching tube S2 and the third switching tube S3 remain off, the fourth switching tube S4 remains on, the fifth switching tube S5, the fifth diode D, the first switching tube S1 and the second inductor L2 form a buck conversion circuit, and the first switching tube S1 and the fifth switching tube S5 cooperate to perform buck conversion, where the second operating mode includes two operating states; a third operating state and a fourth operating state; the third working state: the fifth switch tube S5 is turned on, and the first switch tube S1 is turned off; the fourth working state: the fifth switch tube S5 is turned off, and the first switch tube S1 is turned on.

As shown in fig. 8, in the third operating state, the fifth switching tube S5 is turned on, and the first switching tube S1 is turned off, which can be obtained from kirchhoff' S voltage law, Vin = VL2+ VCo.

In the fourth operating state, as shown in fig. 9, the fifth switch tube S5 is turned off, and the first switch tube S1 is turned on, where VL2= -VCo is obtained from kirchhoff' S voltage law.

Assuming that the duty cycle of the fifth switching tube S5 is Du5, the duty cycle of the first switching tube S1 is 1-Du5, and combining the above expression, the following expression can be obtained according to the volt-second equilibrium law,

−VCo*(1− Du5)+ Du5*(Vin−VCo)=0；

VCo/Vin = Du5 can be obtained. It can be seen from the relational expression of the output voltage and the input voltage that as Du5 goes from 0 to 1, the output ratio input is less than 1, so the operation mode is in the forward buck mode. And the second working mode is matched with the first working mode, so that the high-gain inverter can be realized, the second working mode supplements the part which is absent in the first working mode and has a positive direction of 0-1, and the positive and negative gains which are greater than 1 are realized.

Referring to fig. 10, the present invention further provides a method for controlling a high-gain single-phase inverter, for controlling the operation of the high-gain single-phase inverter, including: when the gain to be achieved is less than 0 or when the gain to be achieved is greater than 1, the high-gain single-phase inverter is in a first working mode, in the first working mode, the fifth switching tube S5 is kept off, and at the moment, the first switching tube S1, the second switching tube S2, the third switching tube S3 and the fourth switching tube S4 work in a matching mode to perform inversion, wherein the second switching tube S2 and the third switching tube S3 are driven to be the same, the first switching tube S1 and the fourth switching tube S4 are driven to be the same, and the first working mode comprises two working states; the first working state: the first switch tube S1 and the fourth switch tube S4 are turned on, and the second switch tube S2 and the third switch tube S3 are turned off; the second working state: the first switch tube S1 and the fourth switch tube S4 are turned off, and the second switch tube S2 and the third switch tube S3 are turned on; when 0< gain to be achieved <1, the discontinuous inverter operation mode cannot meet the operation condition at this time, and is switched to a second operation mode, when in the second operation mode, the second switching tube S2 and the third switching tube S3 are kept off, the fourth switching tube S4 is kept on, a voltage reduction type conversion circuit is formed by the fifth switching tube S5, the fifth diode D, the first switching tube S1 and the second inductor L2, the voltage reduction type conversion circuit is reduced by the cooperation of the first switching tube S1 and the fifth switching tube S5, and the second operation mode comprises two operation states; the third working state: the fifth switch tube S5 is turned on, and the first switch tube S1 is turned off; the fourth working state: the fifth switch tube S5 is turned off, and the first switch tube S1 is turned on; obtaining Msin ω t (M is gain) of the high-gain single-phase inverter in advance, wherein the Msin ω t is a modulation wave of the gain which the high-gain single-phase inverter wants to achieve; then, different working modes are adjusted according to the modulation wave.

The control method of the high-gain single-phase inverter includes that Msin ω t is a modulation wave of a desired gain, when M <0 or M >1, the high-gain single-phase inverter operates in a first operating mode, which is an intermittent inverter operating mode, when M <0 >1, the intermittent inverter operating mode cannot meet an operating condition, the high-gain single-phase inverter switches to a second operating mode, and a Buck circuit continues to operate, so that high gain is achieved.

Specifically, in this embodiment, the calculation formula of the gain of the first operation mode is VCo/Vin = (1-Du)/(1-2 Du). In the first working state, the first switching tube S1 and the fourth switching tube S4 are turned on, the second switching tube S2 and the third switching tube S3 are turned off, and at this time, Vin = VC + VL1 and VL2= VCo according to kirchhoff' S voltage law. In the second working state, the first switching tube S1 and the fourth switching tube S4 are turned off, the second switching tube S2 and the third switching tube S3 are turned on, and Vin = VL1+ VCo and VC = VL2 are obtained from kirchhoff' S voltage law. Assuming that the duty cycles of the first switch tube S1 and the fourth switch tube S4 are Du, the duty cycles of the second switch tube S2 and the third switch tube S3 are 1-Du, and combining the above expressions, the following expressions can be obtained according to the volt-second equilibrium law,

Du*(Vin−VC)+(1−Du)*(Vin−VCo)=0，VCo*Du+(1−Du)*VC=0；

VCo/Vin = (1-Du)/(1-2 Du) can be obtained. It can be seen from the relational expression of the output voltage and the input voltage that when Du is changed from 0 to 0.5, the positive gain is changed from 1 to positive infinity, and when Du is changed from 0.5 to 1, the negative gain is changed from negative infinity to 0, so that the mode operates in the discontinuous inverter mode, and the positive gain part of 0-1 is lacked.

Specifically, in this embodiment, the gain of the second operation mode is calculated as VCo/Vin =1/(1-Du 5). In the third working state, the fifth switching tube S5 is turned on, the first switching tube S1 is turned off, and Vin = VL2+ VCo is obtained according to kirchhoff' S voltage law. In the fourth operating state, the fifth switching tube S5 is turned off, and the first switching tube S1 is turned on, where VL2= -VCo is obtained from kirchhoff' S voltage law. If the duty ratio of the fifth switching tube S5 is Du5, the duty ratio of the first switching tube S1 is 1-Du5, and the following expression, -VCo (1-Du5) + Du5 (Vin-VCo) =0 can be obtained according to the volt-second equilibrium law in combination with the above expression; VCo/Vin = Du5 can be obtained. It can be seen from the relational expression of the output voltage and the input voltage that as Du5 goes from 0 to 1, the output ratio input is less than 1, so the operation mode is in the forward buck mode. The second working mode is matched with the first working mode, so that the inverter with high gain can be realized, the second working mode supplements the part of the first working mode which is lack and has 0-1 positive direction, and the gains of the positive direction and the negative direction which are more than 1 are realized.

It can be understood that, in the high-gain single-phase inverter of the present invention, when the load R is used, the two ends of the load R are connected to the two ends of the second capacitor Co, respectively; the load type may be a resistor, capacitor, inductor, RCD load, etc.

Referring to fig. 11, a three-phase inverter according to a third embodiment of the present invention includes three high-gain single-phase inverters, where the three high-gain single-phase inverters are connected in parallel, and an ac output terminal of each high-gain single-phase inverter is used as a three-phase ac output terminal of the three-phase inverter; the voltage of the three-phase alternating current output end is a U-phase voltage, a V-phase voltage and a W-phase voltage of the three-phase voltage respectively, if a modulation wave generating the U-phase voltage is Msin (ω t), the modulation wave generating the V-phase voltage is Msin (ω t +2 π/3) and the modulation wave generating the W-phase voltage is Msin (ω t-2 π/3) according to the principle of three-phase inversion modulation. Each phase passes through the working modes of fig. 4 to 9, so that three-phase inversion can be realized.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (8)

1. A high-gain single-phase inverter is characterized by comprising a direct-current power supply, a first inductor, a second inductor, a first capacitor, a second bidirectional switch, a first bidirectional switch, a fifth switching tube and a fifth diode;

the positive electrode of the direct-current power supply is respectively connected with the first end of the first inductor and the first end of the fifth switching tube;

the second end of the first inductor is respectively connected with the first end of the first bidirectional switch and the first end of the first capacitor;

a second end of the fifth switching tube is connected with an anode of the fifth diode, and a cathode of the fifth diode is respectively connected with a second end of the first capacitor, a first end of the second bidirectional switch and a first end of the second inductor;

the second end of the second inductor is connected with the second end of the first bidirectional switch and the first end of the second capacitor respectively;

the negative electrode of the direct current power supply, the second end of the second bidirectional switch and the second end of the second capacitor are connected together;

the first bidirectional switch comprises a second switch tube, a third switch tube, a second diode and a third diode, the second switch tube and the third diode are connected in series in the same direction to form a second branch, the third switch tube and the second diode are connected in series in the same direction to form a first branch, a current outflow end of the first branch is connected with a current inflow end of the second branch to form a first end of the first bidirectional switch, and a current inflow end of the first branch is connected with a current outflow end of the second branch to form a second end of the first bidirectional switch; the second bidirectional switch comprises a first switch tube, a fourth switch tube, a first diode and a fourth diode, the first switch tube and the fourth diode are connected in series in the same direction to form a fourth branch, the fourth switch tube and the first diode are connected in series in the same direction to form a third branch, the current outflow end of the third branch is connected with the current inflow end of the fourth branch to form a first end of the second bidirectional switch, and the current inflow end of the third branch is connected with the current outflow end of the fourth branch to form a second end of the second bidirectional switch;

the high-gain single-phase inverter has a first operating mode;

during the first working mode, the fifth switching tube is kept turned off, and at the moment, the first diode to the fourth diode and the first switching tube to the fourth switching tube work cooperatively to invert, and the first working mode comprises two working states:

the first working state: the first switching tube and the fourth diode are conducted, and the second switching tube and the third switching tube are turned off;

the second working state: the first switch tube and the fourth switch tube are turned off, and the second switch tube and the third diode are turned on.

2. The high-gain single-phase inverter according to claim 1, wherein the first branch midpoint is connected to the second branch midpoint, or/and the third branch midpoint is connected to the fourth branch midpoint.

3. The high-gain single-phase inverter according to claim 1, wherein the fifth switch tube is any one of a combination of an IGBT and a diode connected in anti-parallel with the IGBT, a combination of a transistor and a diode connected in anti-parallel with the transistor, a combination of a MOSFET and a diode connected in anti-parallel with the MOSFET, or a MOSFET; the first switch tube, the second switch tube, the third switch tube and the fourth switch tube are any one of an IGBT, a triode or an MOSFET.

4. The high-gain single-phase inverter according to any one of claims 1 to 3, wherein the high-gain single-phase inverter has a second operating mode;

during the second working mode, the second switching tube and the third switching tube are kept turned off, the fourth switching tube is kept turned on, the fifth switching tube, the fifth diode, the first switching tube and the second inductor form a buck conversion circuit, the first switching tube and the fifth switching tube cooperate to work to carry out voltage reduction, and the second working mode comprises two working states:

the third working state: the fifth switching tube is switched on, and the first switching tube is switched off;

the fourth working state: the fifth switch tube is turned off, and the first switch tube is turned on.

5. A control method of a high-gain single-phase inverter for controlling the operation of the high-gain single-phase inverter according to any one of claims 1 to 4, comprising:

when the gain to be achieved is less than 0 or >1, the high-gain single-phase inverter is in a first working mode, and in the first working mode, the fifth switching tube is kept off, and the first switching tube, the second switching tube, the third switching tube and the fourth switching tube work in a matching way to perform inversion, wherein the second switching tube and the third switching tube are driven to be the same, the first switching tube and the fourth switching tube are driven to be the same, and the first working mode comprises two working states;

the first working state: the first switching tube and the fourth switching tube are conducted, and the second switching tube and the third switching tube are disconnected;

the second working state: the first switching tube and the fourth switching tube are turned off, and the second switching tube and the third switching tube are turned on;

when 0< gain to be achieved <1, the first working mode cannot meet working conditions at the moment, and is switched to a second working mode, when the second working mode is adopted, the second switching tube and the third switching tube are kept turned off, the fourth switching tube is kept turned on, a voltage reduction type conversion circuit is formed by the fifth switching tube, the fifth diode, the first switching tube and the second inductor, the first switching tube and the fifth switching tube are matched to work to reduce voltage, and the second working mode comprises two working states;

the third working state: the fifth switching tube is switched on, and the first switching tube is switched off;

the fourth working state: the fifth switch tube is turned off, and the first switch tube is turned on.

6. The method of claim 5, wherein the gain of the first operating mode is calculated as VCo/Vin = (1-Du)/(1-2 Du);

VCo is output voltage, Vin is input voltage, Du is duty ratio of the first switching tube and the fourth switching tube, and 1-Du is duty ratio of the second switching tube and the third switching tube.

7. The method as claimed in claim 5 or 6, wherein the gain of the second operation mode is calculated as VCo/Vin = Du 5;

VCo is output voltage, Vin is input voltage, and Du5 is the duty cycle of the fifth switching tube.

8. A three-phase inverter comprising three high-gain single-phase inverters according to any one of claims 1 to 4, wherein the three high-gain single-phase inverters are connected in parallel, and an ac output terminal of each of the high-gain single-phase inverters is used as a three-phase ac output terminal of the three-phase inverter.

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